Characterization of the nitrosyl adduct of substrate-bound mouse cysteine dioxygenase by electron paramagnetic resonance: electronic structure of the active site and mechanistic implications

Mammalian cysteine dioxygenase (CDO) is a non-heme iron metalloenzyme that catalyzes the first committed step in oxidative cysteine catabolism. The active site coordination of CDO comprises a mononuclear iron ligated by the Nepsilon atoms of three protein-derived histidines, thus representing a new variant on the 2-histidine-1-carboxylate (2H1C) facial triad motif. Nitric oxide was used as a spectroscopic probe in investigating the order of substrate-O2 binding by EPR spectroscopy. In these experiments, CDO exhibits an ordered binding of l-cysteine prior to NO (and presumably O2) similar to that observed for the 2H1C class of non-heme iron enzymes. Moreover, the CDO active site is essentially unreactive toward NO in the absence of substrate, suggesting an obligate ordered binding of l-cysteine prior to NO. Typically, addition of NO to a mononuclear non-heme iron center results in the formation of an {FeNO}7 (S = 3/2) species characterized by an axial EPR spectrum with gx, gy, and gz values of approximately 4, approximately 4, and approximately 2, respectively. However, upon addition of NO to CDO in the presence of substrate l-cysteine, a low-spin {FeNO}7 (S = 1/2) signal that accounts for approximately 85% of the iron within the enzyme develops. Similar {FeNO}7 (S = 1/2) EPR signals have been observed for a variety of octahedral mononuclear iron-nitrosyl synthetic complexes; however, this type of iron-nitrosyl species is not commonly observed for non-heme iron enzymes. Substitution of l-cysteine with isosteric substrate analogues cysteamine, 3-mercaptopropionic acid, and propane thiol did not produce any analogous {FeNO}7 signals (S = 1/2 or 3/2), thus reflecting the high substrate specificity of the enzyme observed by a number of researchers. The unusual {FeNO}7 (S = 1/2) electronic configuration adopted by the substrate-bound iron-nitrosyl CDO (termed {ES-NO}7) is a result of the bidentate thiol/amine coordination of l-cysteine in the NO-bound CDO active site. DFT computations were performed to further characterize this species. The DFT-predicted geometric parameters for {ES-NO}7 are in good agreement with the crystallographically determined substrate-bound active site configuration of CDO and are consistent with known iron-nitrosyl model complexes. Moreover, the computed EPR parameters (g and A values) are in excellent agreement with experimental results for this CDO species and those obtained from comparable synthetic {FeNO}7 (S = 1/2) iron-nitrosyl complexes.     

Involvement of lymphocyte mediators in the rejection of a murine tumor allograft

Macrophage migration inhibition by peritoneal leukocytes was studied in BALB/c mice bearing intraperitoneal allogeneic EL-4 lymphomas to explore the role of this immune effector function in allograft rejection. The nonadherent peritoneal leukocyte population harvested between 8 and 10 days after allograft inoculation inhibited migration of nonimmune murine macrophages as demonstrated by both direct and indirect migration assays using the agarose droplet method. This host response also contained large numbers of adherent macrophages which others have shown to be cytotoxic to EL-4 target cells. These findings provide direct evidence for lymphokine activity in allograft rejection and suggest that lymphocyte mediators may attract and activate the cytotoxic macrophages observed in this response.     

Caloric restriction increases free radicals and inducible nitric oxide synthase expression in mice infected with Salmonella Typhimurium

It is well known that CR (caloric restriction) reduces oxidative damage to proteins, lipids and DNA, although the underlying mechanism is unclear. However, information concerning the effect of CR on the host response to infection is sparse. In this study, 6-month-old mice that were fed AL (ad libitum) or with a CR diet were infected with Salmonella serovar Typhimurium. EPR (electron paramagnetic resonance; also known as ESR (electron spin resonance)) was used to identify FRs (free radicals). These results were subsequently correlated with SOD (superoxide dismutase) catalytic activity, iNOS [inducible NOS (nitric oxide synthase) or NOSII] expression and NO (nitric oxide) content. EPR analysis of liver samples demonstrated that there was a higher quantity of FRs and iron-nitrosyl complex in infected mice provided with a CR diet as compared with those on an AL diet, indicating that CR was beneficial by increasing the host response to Salmonella Typhimurium. Furthermore, in infected mice on the CR diet, NOSII expression was higher, NO content was greater and spleen colonization was lower, compared with mice on the AL diet. No changes in SOD activity were detected, indicating that the NO produced participated more in the formation of iron-nitrosyl complexes than peroxynitrite. These results suggest that CR exerts a protective effect against Salmonella Typhimurium infection by increasing NO production.     

Critical role of effector macrophages in mediating CD4-dependent alloimmune injury of transplanted liver parenchymal cells

Despite the recognition that humoral rejection is an important cause of allograft injury, the mechanism of Ab-mediated injury to allograft parenchyma is not well understood. We used a well-characterized murine hepatocellular allograft model to determine the mechanism of Ab-mediated destruction of transplanted liver parenchymal cells. In this model, allogeneic hepatocytes are transplanted into CD8-deficient hosts to focus on CD4-dependent, alloantibody-mediated rejection. Host serum alloantibody levels correlated with in vivo allospecific cytotoxic activity in CD8 knockout hepatocyte rejector mice. Host macrophage depletion, but not CD4(+) T cell, NK cell, neutrophil, or complement depletion, inhibited in vivo allocytotoxicity. Recipient macrophage deficiency delayed CD4-dependent hepatocyte rejection and inhibited in vivo allocytotoxicity without influencing alloantibody production. Furthermore, hepatocyte coincubation with alloantibody and macrophages resulted in Ab-dependent hepatocellular cytotoxicity in vitro. These studies are consistent with a paradigm of acute humoral rejection in which CD4(+) T cell-dependent alloantibody production results in the targeting of transplanted allogeneic parenchymal cells for macrophage-mediated cytotoxic immune damage. Consequently, strategies to eliminate recipient macrophages during CD4-dependent rejection pathway may prolong allograft survival.     

Role of nitric oxide and superoxide in acute cardiac allograft rejection in rats

The role of NO and superoxide (O(2)(-)) in tissue injury during cardiac allograft rejection was investigated by using a rat ex vivo organ perfusion system. Excessive NO production and inducible NO synthase (iNOS) expression were observed in cardiac allografts at 5 days after cardiac transplantation, but not in cardiac isografts, as identified by electron spin resonance spectroscopy and Northern blotting. Cardiac isografts or allografts obtained on Day 5 after transplantation were perfused with Krebs bicarbonate buffer with or without various antidotes for NO or O(2)-, including N(omega)-monomethyl-L-arginine (L-NMMA; 1 mM), 2-phenyl-4,4,5, 5-tetramethylimidazoline-1-oxyl 3-oxide (PTIO; 100 microM), 4-amino-6-hydroxypyrazolo[3,4-d]pyrimidine (AHPP; a xanthine oxidase inhibitor; 100 microM), and superoxide dismutase (SOD; 100 units/ml). Treatment of the cardiac allografts with PTIO showed most remarkable improvement of the cardiac injury as revealed by significant reduction in aspartate transaminase, lactate dehydrogenase, and creatine phosphokinase concentrations in the perfusate. Similar but less potent protective effect on the allograft injury was observed by treatment with L-NMMA, AHPP, and SOD. Immunohistochemical analyses for iNOS and nitrotyrosine indicated that iNOS is mainly expressed by macrophages infiltrating the allograft tissues, and nitrotyrosine formation was demonstrated not only in macrophages but also in cardiac myocytes of the allografts, providing indirect evidence for the generation of peroxynitrite during allograft rejection. Our results suggest that tissue injury in rat cardiac allografts during acute rejection is mediated by both NO and O(2)(-), possibly through peroxynitrite formation.     

Acute rejection of allografted CTL-susceptible leukemia cells from perforin/Fas ligand double-deficient mice

The generation of knockout mice demonstrated that CD4(+), but not CD8(+), T cells were essential for the rejection of allografted skin or heart, presumably because these targets were CTL resistant. In the case of CTL-susceptible targets (e.g., P815 mastocytoma cells and EL-4 or RLmale1 T lymphoma cells), however, it is assumed that the CTL is the effector cell responsible for allograft rejection and that perforin and Fas ligand (FasL) pathways are the killing mechanisms. In the present study, we examined the role of these cytotoxic molecules in the rejection of i.p. allografted CTL-susceptible leukemia cells. Unexpectedly, the allografted leukemia cells were acutely rejected from gld (a mutation of FasL), perforin(-/-), or double-deficient mice. The peritoneal exudate cells from gld or normal mice showed T cell-, TCRalphabeta-, and perforin-dependent cytotoxic activity against the allograft, whereas the exudate cells from perforin(-/-) mice exhibited almost full cytotoxic activity in the presence of Fas-Fc. Furthermore, the infiltrates from double-deficient mice showed a high cytotoxic activity against the allografted cells even in the presence of anti-TCRalphabeta Ab or in the absence of T cells. The cytotoxic cells appeared to be macrophages, because they were Mac-1(+) mononuclear cells with a kidney- or horseshoe-shaped nucleus and because the cytotoxic activity was completely suppressed by the addition of N(G)-monomethyl-l-arginine, an inhibitor of inducible NO synthase. These results indicate that macrophages are ready and available to kill CTL-susceptible allografts when CTLs lack both perforin and FasL molecules.     

Interleukin-1 beta-induced formation of EPR-detectable iron-nitrosyl complexes in islets of Langerhans. Role of nitric oxide in interleukin-1 beta-induced inhibition of insulin secretion.

The molecular mechanism by which interleukin (IL)-1 inhibits insulin secretion and ultimately causes destruction of the pancreatic beta-cell remains unknown. Evidence is presented which suggests that IL-1 beta-induced inhibition of insulin secretion is dependent on the metabolism of L-arginine to nitric oxide. NG-Monomethylarginine, a competitive inhibitor of the L-arginine-dependent enzyme nitric oxide synthase, completely prevents IL-1-induced inhibition of glucose-stimulated insulin secretion as well as nitrite production by islets. It is further shown that IL-1 beta induces nitric oxide formation in islets as evidenced by an electron paramagnetic resonance feature at g = 2.04 which is similar to previously reported iron-nitrosyl complexes formed from the destruction of iron-sulfur centers by nitric oxide. Inhibition of the nitric oxide synthase by NG-monomethylarginine completely prevents the formation of this EPR signal in islets. These results show that IL-1-induced inhibition of insulin secretion is mediated through formation of nitric oxide and suggest that the generation of nitric oxide may represent the cellular mechanism responsible for beta-cell destruction.     

Spectroscopic evidence for a copper-nitrosyl intermediate in nitrite reduction by blue copper-containing nitrite reductase

The reactions of nitrogen monoxide (NO) with the blue copper-containing nitrite reductases from Alcaligenes sp. NCIB 11015 and Achromobacter cycloclastes IAM 1013 were investigated spectroscopically. The electron paramagnetic resonance (EPR) signals of the blue coppers vanished in the presence of NO at 77 K, being fully restored by the removal of NO. The additions of NO to the enzyme solutions resulted in the substantial bleaching of the visible absorption bands at room temperature. The reactions were also completely reversible. These results suggest the formation of a cuprous nitrosyl complex (Cu+-NO+), which is likely the intermediate in the enzymatic nitrite reduction.     

Inhibition of nitrogenase by nitrite and nitric oxide in Rhodopseudomonas sphaeroides f. sp. denitrificans

In cells of Rhodopseudomonas sphaeroides f. sp. denitrificans nitrite and nitric oxide, the products of denitrification, inhibit activity of nitrogenase enzyme.Ferredoxin-linked CO₂ fixation, with H₂ as a reductant, was also inhibited by nitrite and NO in denitrifying cells.EPR spectroscopy of cell preparations treated with NO showed that it reacts with non-haem iron-sulphur proteins to form iron-nitrosyl complexes. Nitrite also reacts with these iron-sulphur proteins, but the formation of ironnitrosyl complexes was dependent on the presence of dithionite. Since nitrite is reduced to NO by dithionite it is likely that nitrogenase and CO₂ fixation reactions are inhibited not only by nitrite itself, but also by nitric oxide.Abbreviation DPPH 1,1-diphenyl-2-picrylhydrazyl     

Role of paraquat in the uncoupling of nitric oxide synthase

Nitric oxide synthase (NOS) oxidizes L-arginine to NO(&z.ccirf;) and L-citrulline. Recent studies have shown that this enzyme can also generate O(2)(&z.ccirf;-) during its enzymatic cycling. Herein, we used spin trapping and electron paramagnetic resonance (EPR) spectroscopy to investigate the impact paraquat has on the transport of electrons through purified neuronal NOS (NOS I). In a concentration-dependent manner, ranging from 10-100 microM of paraquat, paraquat free radical was observed under anaerobic conditions. This demonstrates that NOS shunts electrons to paraquat, thereby uncoupling this enzyme. This resulted in enhanced production of O(2)(&z.ccirf;-) at the expense of NO(&z.ccirf;). Experiments demonstrated that the reductase domain is the site of paraquat-mediated uncoupling of NOS.     

Simultaneous measurement of NO(*) and PO(2) from tissue by in vivo EPR.

We describe a technique that utilizes electron paramagnetic resonance (EPR) to measure NO(*) and pO(2) directly, and non-invasively, from tissue in vivo. Diethyldithiocarbamate (DETC) was injected with iron so as to complex with NO(*) in the tissue. Gloxy (an oxygen-sensitive, paramagnetic material) was also implanted into the tissue of interest (brain or liver). Because the signals arising from gloxy and NO-Fe-(DETC)(2) did not overlap, they could be monitored and measured simultaneously in vivo. The gloxy was not responsive to NO(*) and/or DETC. As model systems we either injected SNP (an NO(*) donor) into animals and monitored NO(*) and pO(2) simultaneously from brain, or endotoxin (lipopolysaccharide; LPS) was injected in order to induce a septic episode and NO(*) and pO(2) measured from liver. We found a close correlation between levels of SNP-derived NO(*) and brain pO(2) in vivo. During sepsis, liver pO(2) decreased dramatically at 300-360 min after endotoxin injection, and this coincided with decreases in mean arterial blood pressure and increased tissue NO(*) detected. These studies demonstrate the potential usefulness of this technique for making direct in vivo measurements of NO(*) and pO(2) simultaneously from tissue.     

Components of cytochrome c oxidase detectable by EPR spectroscopy

A procedure for the preparation from frozen beef heart mitochondria of cytochrome c oxidase (EC 1.9.3.1) of high heme ( 14 μmoles/mg protein) and low extraneous copper ( 1.1 atoms Cu/mole heme) and low lipid ( 0.05 g phospholipid/g protein) content is described. EPR signals observed with the enzyme between 6 and 100 °K at various states of oxidation and at different conditions of pH and presence of solutes are described in detail. The quantities of paramagnetic species represented by these signals are estimated. Under no conditions does the sum of the EPR detectable species represent more than approx. 50% of the potentially paramagnetic components of the enzyme. Comparisons are made to the corresponding signals as observed in whole tissue, mitochondria and submitochondrial particles from a number of species. The assignment of the observed signals to known components of cytochrome c oxidase is discussed briefly.     

Extensive studies of the heme coordination structure of indoleamine 2,3-dioxygenase and of tryptophan binding with magnetic and natural circular dichroism and electron paramagnetic resonance spectroscopy

In order to probe the active site of the heme protein indoleamine 2,3-dioxygenase, magnetic and natural circular dichroism (MCD and CD) and electron paramagnetic resonance (EPR) studies of the substrate (L-tryptophan)-free and substrate-bound enzyme with and without various exogenous ligands have been carried out. The MCD spectra of the ferric and ferrous derivatives are similar to those of the analogous myoglobin and horseradish peroxidase species. This provides strong support for histidine imidazole as the fifth ligand to the heme iron of indoleamine 2,3-dioxygenase. The substrate-free native ferric enzyme exhibits predominantly high-spin EPR signals (g perpendicular = 6, g parallel = 2) along with weak low-spin signals (g perpendicular = 2.86, 2.28, 1.60); similar EPR, spin-state and MCD features are found for the benzimidazole adduct of ferric myoglobin. This suggests that the substrate-free ferric enzyme has a sterically hindered histidine imidazole nitrogen donor sixth ligand. Upon substrate binding, noticeable MCD and EPR spectral changes are detected that are indicative of an increased low spin content (from 30 to over 70% at ambient temperature). Concomitantly, new low spin EPR signals (g = 2.53, 2.18, 1.86) and MCD features characteristic of hydroxide complexes of histidine-ligated heme proteins appear. For almost all of the other ferric and ferrous derivatives, only small substrate effects are observed with MCD spectroscopy, while substantial substrate effects are seen with CD spectroscopy. Thus, changes in the heme coordination structure of the ferric enzyme and in the protein conformation at the active site of the ferric and ferrous enzyme are induced by substrate binding. The observed substrate effects on the ferric enzyme may correlate with the previously observed kinetic substrate inhibition of indoleamine 2,3-dioxygenase activity, while such effects on the ferrous enzyme suggest the possibility that the substrate is activated during turnover.     

Structure of a substrate radical intermediate in the reaction of lysine 2,3-aminomutase.

Electron paramagnetic resonance (EPR) spectroscopy has been used to characterize an organic radical that appears in the steady state of the reaction catalyzed by lysine 2,3-aminomutase from Clostridium SB4. Results of a previous electron paramagnetic resonance (EPR) study [Ballinger, M. D., Reed, G. H., & Frey, P. A. (1992) Biochemistry 31, 949-953] demonstrated the presence of EPR signals from an organic radical in reaction mixtures of the enzyme. The materialization of these signals depended upon the presence of the enzyme, all of its cofactors, and the substrate, lysine. Changes in the EPR spectrum in response to deuteration in the substrate implicated the carbon skeleton of lysine as host for the radical center. This radical has been further characterized by EPR measurements on samples with isotopically substituted forms of lysine and by analysis of the hyperfine splittings in resolution-enhanced spectra by computer simulations. Changes in the hyperfine splitting patterns in EPR spectra from samples with [2-2H]lysine and [2-13C]-lysine show that the paramagnetic species is a pi-radical with the unpaired spin localized primarily in a p orbital on C2 of beta-lysine. In the EPR spectrum of this radical, the alpha-proton, the beta-nitrogen, and the beta-proton are responsible for the hyperfine structure. Analysis of spectra for reactions initiated with L-lysine, [3,3,4,4,5,5,6,6-2H8]lysine, [2-2H]lysine, perdeuteriolysine, [alpha-15N]lysine, and [alpha-15N,2-2H]lysine permit a self-consistent assignment of hyperfine splittings.(ABSTRACT TRUNCATED AT 250 WORDS)     

Infiltration of H-2d-specific cytotoxic macrophage with unique morphology into rejection site of allografted meth A (H-2d) tumor cells in C57BL/6 (H-2b) mice

It is assumed that CD8(+) cytotoxic T lymphocytes (CTLs) mediate direct lysis of allografts and that their growth, differentiation, and activation are dependent upon cytokine production by CD4(+) helper T lymphocytes. In the present study, the effector cells responsible for the rejection of i.p. allografted, CTL-resistant Meth A tumor cells from C57BL/6 mice were characterized. The cytotoxic activity was associated exclusively with peritoneal exudate cells and not with the cells in lymphoid organs or blood. On day 8, when the cytotoxic activity reached a peak, 3 types of cells (i.e., lymphocytes, granulocytes, and macrophages) infiltrated into the rejection site; and allograft-induced macrophages (AIM) were cytotoxic against the allograft. Bacterially-elicited macrophages also exhibited cytotoxic activity (approximately 1/2 of that of AIM) against Meth A cells, whereas the cytotoxic activity of AIM against these cells but not that of bacterially-elicited macrophages was completely inhibited by the addition of donor (H-2(d))-type lymphoblasts, suggesting H-2(d)-specific cytotoxicity of AIM against Meth A cells. In contrast, resident macrophages were inactive toward Meth A cells. Morphologically, the three-dimensional appearance of AIM showed them to be unique large elongated cells having radiating peripheral filopodia and long cord-like extensions arising from their cytoplasmic surfaces. The ultrastructural examination of AIM revealed free ribosomes in their cytoplasm, which was often deformed by numerous large digestive vacuoles. These results indicate that AIM are the H-2(d)-specific effector cells for allografted Meth A cells and are a more fully activated macrophage with unique morphological features.     

In Situ Measurement of Nitric Oxide Production in Cardiac Isografts and Rejecting Allografts by an Electrochemical Method

A number of previous studies have indirectly (electron paramagnetic resonance, nitrite/nitrate, ribonuclease protection assay for inducible nitric oxide synthase (iNOS) mRNA, l-citrulline assay) demonstrated the production of nitrogen monoxide (NO) during early cardiac allograft rejection. This study reports the first direct, quantitative measurement using an electrochemical method of NO produced from rejecting allograft tissue studied in vitro. A rat heterotopic abdominal transplant preparation was utilized. Day 7 isograft (ACI to ACI) or allograft (Lewis to ACI) transplanted hearts were atraumatically harvested and suspended at 4 degrees C in Ringers-Hepes solution. An electrochemical system highly sensitive and specific for NO consisting of a Nafion-coated platinum disk electrode (lower limit, 50 nM NO) coupled to an analysis system measured ongoing oxidation of NO. Measurements were carried out after inserting the electrode in the tissue block and warming the block to 25 degrees C. Additional measurements were also made after incubation of tissue with aminoguanidine (AG), a relatively selective iNOS inhibitor. Direct measurements (mean +/- SEM) from allograft tissue indicated a fourfold increase in NO as compared with isografts (13.41 +/- 4.40 microM NO vs. 3.43 +/- 2.04 microM NO). Incubation of allograft tissue with AG reduced NO levels to isograft levels (13.41 +/- 4.40 microM NO vs. 5.94 +/- 3.14 microM NO); AG had no effect on measured isograft NO levels. Direct, quantitative measurement of NO from tissue is feasible and reproducible, and discrimination between different levels of NO production can be made. These results confirm the imputed results from the previous studies using this experimental model. This technology promises to be a valuable tool for evaluating specific modulators of NO production studied under a variety of physiologic and pathophysiologic conditions.     

Binding of nitric oxide to reduced L-tryptophan-2,3-dioxygenase as studied by electron paramagnetic resonance.

Ferrous L-tryptophan-2,3-dioxygenase reacts with nitric oxide both in the presence and in the absence of L-tryptophan. Electron paramagnetic resonance studies suggest that the proximal ligand of the heme is a nitrogen atom, probably from an histidyl residue. The interaction of the protein with substrate changes both the symmetry of the paramagnetic center and the mode of interaction of the iron atom with its two axial ligands, NO and the proximal nitrogen atom. Optical absorption and EPR spectra suggest that the affinity of NO for tryptophan dioxygenase increases in the order: tryptophan dioxygenase, tryptophan dioxygenase + alpha-methyltryptophan, tryptophan diogenase " 5-hydroxytryptophan, tryptophan dioxygenase + L-tryptophan. A possible correlation between the number of superhyperfine lines in the EPR spectrum and the affinity of the enzyme for NO is discussed.     

NO binding and dynamics in reduced heme-copper oxidases aa3 from Paracoccus denitrificans and ba3 from Thermus thermophilus

Cytochrome c oxidase (CcO) has a high affinity for nitric oxide (NO), a property involved in the regulation of respiration. It has been shown that the recombination kinetics of photolyzed NO with reduced CcO from Paracoccus denitrificans on the picosecond time scale depend strongly on the NO/enzyme stoichiometry and inferred that more than one NO can be accommodated by the active site, already at mildly suprastoichiometric NO concentrations. We have largely extended these studies by monitoring rebinding dynamics from the picosecond to the microsecond time scale, by performing parallel steady-state low-temperature electron paramagnetic resonance (EPR) characterizations on samples prepared similarly as for the optical experiments and comparing them with molecular-modeling results. A comparative study was performed on CcO ba(3) from Thermus thermophilus, where two NO molecules cannot be copresent in the active site in the steady state because of its NO reductase activity. The kinetic results allow discrimination between different models of NO-dependent recombination and show that the overall NO escape probability out of the protein is high when only one NO is bound to CcO aa(3), whereas strong rebinding on the 15-ns time scale was observed for CcO ba(3). The EPR characterizations show similar results for aa(3) at substoichiometric NO/enzyme ratios and for ba(3), indicating formation of a 6-coordinate heme-NO complex. The presence of a second NO molecule in the aa(3) active site strongly modifies the heme-NO EPR spectrum and can be rationalized by a rotation of the Fe-N-O plane with respect to the histidine that coordinates the heme iron. This proposal is supported by molecular-modeling studies that indicate a approximately 63 degrees rotation of heme-bound NO upon binding of a second NO to the close-lying copper center CuB. It is argued that the second NO binds to CuB.     

The effect of captopril on nitric oxide formation and on generation of radical forms of mitochondrial respiratory chain compounds in ischemic rat heart.

The increase of radical forms of mitochondrial respiratory chain compounds (MRCC) is an indicator of an increased risk of the formation of oxygen radicals. Using electron paramagnetic resonance (EPR), we found an increase of signals corresponding to ubisemichinone radical (.QH) and ironsulfur proteins radical forms (-FeS) of these respiratory chain compounds during ischemia in the isolated perfused rat heart (.QH increased from 1.51 to 3.08, .FeS1 from 1.14 to 2.65 arbitrary units). During the 5-min reperfusion, the signals returned to normoxic levels. In isolated mitochondria exposed to anoxia and reoxygenation the radical forms of .QH and FeS2 changed in a similar manner as in the intact heart. A combination of in vivo captopril treatment and in vitro L-arginine administration significantly decreased the levels of MRCC radicals in the isolated myocardium (.QH from 2.61 to 1.72 and .FeS, from 1.82 to 0.46 under normoxia; .QH from 4.35 to 2.66 and .FeS1 from 1.93 to 1.35 during ischemia). This decrease in MRCC radical forms was associated with increased NO levels in the perfusate, determined as NO2- / NO3-, as well as tissue NO levels determined using EPR as the dinitrosyl iron complex (DNIC). These results provide new information about the cardioprotective effects of ACE inhibitors and L-arginine.